Methods and systems for accessing memory cells

ABSTRACT

The present disclosure relates to a method for reading memory cells, and may include applying a first read voltage to a plurality of memory cells, detecting first threshold voltages exhibited by the plurality of memory cells in response to application of the first read voltage, associating a first logic state to one or more cells of the plurality of memory cells, applying a second read voltage to the plurality of memory cells, where the second read voltage has the same polarity of the first read voltage and a higher magnitude than an expected highest threshold voltage of memory cells in the first logic state, and detecting second threshold voltages exhibited by the plurality of memory cells in response to application of the second read voltage, among other aspects. A related circuit, a related memory device and a related system are also disclosed.

CROSS REFERENCE

The present Application for Patent is a continuation of U.S. patentapplication Ser. No. 16/771,657 to Di Vincenzo et al., titled “METHODSAND SYSTEMS FOR ACCESSING MEMORY CELLS,” filed Jun. 10, 2020, which is a371 national phase filing of and claims priority to and the benefit ofInternational Patent Application No. PCT/IB2019/001204 to Di Vincenzo etal., titled “METHODS AND SYSTEMS FOR ACCESSING MEMORY CELLS,” filed Dec.3, 2019, each of which is assigned to the assignee hereof, and each ofwhich is expressly incorporated herein by reference in its entirety.

TECHNICAL FIELD

The present disclosure relates to methods and systems for accessingmemory cells, and more particularly for reading memory cells havingdifferent polarities.

BACKGROUND

Memory devices are used in many electronic systems such as mobilephones, personal digital assistants, laptop computers, digital camerasand the like. Nonvolatile memories retain their contents when power isswitched off, making them good choices in memory devices for storinginformation that is to be retrieved after a system power-cycle.

Continued drive to smaller and more energy efficient devices hasresulted in scaling issues with traditional memory devices. Thus, thereis a current demand for memory devices that can potentially scalesmaller than traditional memory devices. However, some memorytechnologies that scale smaller than traditional devices can experiencerelatively high rates of errors.

Traditional systems typically implement error detection and correctionmechanisms to handle errors and prevent system crashes, loss ofinformation, or both. However, error correction mechanisms can increasesystem cost, occupy space on a memory die, and increase the amount oftime for accurate retrieval of data from memory. Such drawbacks can beespecially significant for larger or more complex error correctingsystems used for memories systems with high error rates.

It is therefore desirable to reduce in a simple manner the error ratesin memory devices, particularly to reduce read errors.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exemplary block scheme illustrating an exemplary memorycell that can be read according to the present disclosure;

FIG. 2 schematically illustrates a portion of an exemplary memory cellarray;

FIG. 3 schematically illustrates a single polarity read with a negativepolarity of a memory cell;

FIG. 4 is a graph of experimental data showing lower and higherthreshold voltages exhibited by an exemplary memory cell;

FIG. 5A schematically illustrates a read operation of cells withdifferent polarity;

FIG. 5B is a table representing the effect of the read of FIG. 5A;

FIG. 6A is a graph illustrating a distribution of threshold voltagesexhibited by a plurality of memory cells in response to a positivepolarity read;

FIG. 6B is a graph illustrating a distribution of threshold voltagesexhibited by a plurality of memory cells in response to a negativepolarity read;

FIG. 7 schematically illustrates a read sequence of a memory cellaccording to an embodiment of the present disclosure;

FIGS. 8A-8F are graphs illustrating distributions of threshold voltagesexhibited by memory cells during the read sequence according to anembodiment of present disclosure;

FIG. 9 is a table illustrating the outcomes of the read sequenceaccording to an embodiment the present disclosure;

FIG. 10A is a flow diagram representing steps of a method according tothe present disclosure;

FIG. 10B is a flow diagram representing steps of a method according toan embodiment of the present disclosure; and

FIG. 11 shows a schematic block diagram of a system including a memorydevice according to the disclosure.

DETAILED DESCRIPTION

With reference to those drawings, methods and systems for an improvedread of memory cells will be disclosed herein.

Nonvolatile memories retain their contents when power is switched off,making them good choices for storing information that is to be retrievedafter a system power-cycle. A Flash memory is a type of nonvolatilememory that retains stored data and is characterized by a very fastaccess time. Moreover, it can be erased in blocks instead of one byte ata time. Each erasable block of memory comprises a plurality ofnonvolatile memory cells arranged in a matrix of rows and columns. Eachcell is coupled to an access line and/or a data line. The cells areprogrammed and erased by manipulating the voltages on the access anddata lines. Flash memories are well established and well suited for massstorage applications; however, their performances do not meet presentday most demanding applications. New technologies, for example 3D CrossPoint (3D XPoint) memories and Self-Selecting Memories (SSM) have betterperformances, for example in terms of access time and access granularity(data may be programmed and read with page, word or—in principle—evenbit granularity). Accessing data during a read operation is more andmore challenging with scaled technologies.

FIG. 1 illustrates a block scheme of an exemplary memory cell 100 thatcan be written and read according to the present disclosure.

In the embodiment illustrated in FIG. 1, the memory cell 100 includes astorage material 102 between access lines 104 and 106. The access lines104, 106 electrically couple the memory cell 100 with circuitry 142 thatwrites to and reads the memory cell 100. The term “coupled” can refer toelements that are physically, electrically, and/or communicativelyconnected either directly or indirectly, and may be used interchangeablywith the term “connected” herein. Physical coupling can include directcontact. Electrical coupling includes an interface or interconnectionthat allows electrical flow and/or signaling between components.Communicative coupling includes connections, including wired andwireless connections, that enable components to exchange data.

In one embodiment, the storage material 102 includes a self-selectingmaterial that exhibits memory effects. A self-selecting material is amaterial that enables selection of a memory cell in an array withoutrequiring a separate selector element. Thus, FIG. 1 illustrates thestorage material 102 as a “selector/storage material.” A materialexhibits memory effects if circuitry for accessing memory cells cancause the material to be in one of multiple states (e.g., via a writeoperation), and later determine the programmed state (e.g., via a readoperation). Circuitry for accessing memory cells (e.g., via read andwrite operations) is referred to generally as “access circuitry,” and isdiscussed further below with reference to access circuitry 143. Accesscircuitry can store information in the memory cell 100 by causing thestorage material 102 to be in a particular state. The storage material102 can include, for example, a chalcogenide material such as Te—Sealloys, As—Se alloys, Ge—Te alloys, As—Se—Te alloys, Ge—As—Se alloys,Te—As—Ge alloys, Si—Ge—As—Se alloys, Si—Te—As—Ge alloys, or othermaterial capable of functioning as both a storage element and aselector, to enable addressing a specific memory cell and determiningwhat the state of the memory cell is. Thus, in one embodiment, thememory cell 100 is a self-selecting memory cell that includes a singlelayer of material that acts as both a selector element to select thememory cell and a memory element to store a logic state, i.e. a staterelated to a given polarity of the cell.

In one embodiment, the storage material 102 is a phase change material.A phase change material can be electrically switched between a generallyamorphous and a generally crystalline state across the entire spectrumbetween completely amorphous and completely crystalline states. Inanother embodiment, the storage material 102 is not a phase changematerial. In one embodiment in which the storage material 102 is not aphase change material, the storage material is capable of switchingbetween two or more stable states without changing phase. The accesscircuitry 143 is able to program the memory cell 100 by applying avoltage with a particular polarity to cause the storage material 102 tobe in the desired stable state.

In one such embodiment, programming the memory cell 100 causes thememory cell 100 to “threshold” or undergo a “threshold event.” When amemory cell thresholds (e.g., during a program voltage pulse), thememory cell undergoes a physical change that causes the memory cell toexhibit a certain threshold voltage in response to the application of asubsequent voltage (e.g., a read voltage with a particular magnitude andpolarity). Programming the memory cell 100 can therefore involveapplying a voltage of a given polarity to induce a programming thresholdevent, which causes the memory cell 100 to exhibit a particularthreshold voltage at a subsequent reading voltage of a same or differentpolarity. In one such embodiment, the storage material 102 is aself-selecting material (e.g., a non-phase change chalcogenide materialor other self-selecting material) that can be programmed by inducing athreshold event.

As it is explained in further detail below, the output of such a memorycell when read differs as a function of the polarity used to program thememory cell and the polarity used to read the memory cell. For example,the storage material 102 can exhibit a “lower threshold voltage” or a“higher threshold voltage” in response to a read voltage pulse based onthe polarity of both the programming and read voltages. In the contextof the present disclosure, exhibiting a threshold voltage means thatthere is a voltage across the memory cell that is approximately equal tothe threshold voltage in response to the application of a voltage with aparticular magnitude and polarity to the terminals of the memory cell.The threshold voltage thus corresponds to the minimum voltage that isneeded to be applied at the input(s) to produce output(s), i.e. to see adetermined electrical response of the cell. In other words, in thecontext of the present disclosure, the verb “threshold” means that thecells undergo a threshold event, i.e. they have an electrical responsein response to the applied voltage that is above a given threshold, thusexhibiting a peculiar threshold voltage.

As mentioned above, the access lines 104, 106 electrically couple thememory cell 100 with circuitry 142. The access lines 104, 106 can bereferred to as a bitline and wordline, respectively. The wordline is foraccessing a particular word in a memory array and the bitline is foraccessing a particular bit in the word. The access lines 104, 106 can becomposed of one or more metals including: Al, Cu, Ni, Cr, Co, Ru, Rh,Pd, Ag, Pt, Au, Ir, Ta, and W; conductive metal nitrides including TiN,TaN, WN, and TaCN; conductive metal silicides including tantalumsilicides, tungsten silicides, nickel silicides, cobalt silicides andtitanium silicides; conductive metal silicide nitrides including TiSiNand WSiN; conductive metal carbide nitrides including TiCN and WCN, orany other suitable electrically conductive material.

In one embodiment, electrodes 108 are disposed between storage material102 and access lines 104, 106. Electrodes 108 electrically couple accesslines 104, 106 with storage material 102. Electrodes 108 can be composedof one or more conductive and/or semiconductive materials such as, forexample: carbon (C), carbon nitride (CxNy); n-doped polysilicon andp-doped polysilicon; metals including, Al, Cu, Ni, Cr, Co, Ru, Rh, Pd,Ag, Pt, Au, Ir, Ta, and W; conductive metal nitrides including TiN, TaN,WN, and TaCN; conductive metal silicides including tantalum silicides,tungsten silicides, nickel silicides, cobalt silicides and titaniumsilicides; conductive metal silicides nitrides including TiSiN and WSiN;conductive metal carbide nitrides including TiCN and WCN; conductivemetal oxides including RuO2, or other suitable conductive materials. Inone embodiment, conductive wordline layer can include any suitable metalincluding, for example, metals including, Al, Cu, Ni, Cr, Co, Ru, Rh,Pd, Ag, Pt, Au, Ir, Ta, and W; conductive metal nitrides including TiN,TaN, WN, and TaCN; conductive metal silicides including tantalumsilicides, tungsten silicides, nickel silicides, cobalt silicides andtitanium silicides; conductive metal silicides nitrides including TiSiNand WSiN; conductive metal carbide nitrides including TiCN and WCN, oranother suitable electrically conductive material.

Referring again to the circuitry 142, the access lines 104, 106communicatively couple the circuitry 142 to the memory cell 100, inaccordance with an embodiment. The circuitry 142 includes accesscircuitry 143 and sense circuitry 145. Circuitry includes electroniccomponents that are electrically coupled to perform analog or logicoperations on received or stored information, output information, and/orstore information. Hardware logic is circuitry to perform logicoperations such as logic operations involved in data processing. In oneembodiment, the access circuitry 143 applies voltage pulses to theaccess lines 104, 106 to write to or read the memory cell 100. The terms“write” and “program” are used interchangeably to describe the act ofstoring information in a memory cell. To write to the memory cell 100,the access circuitry applies a voltage pulse with a particular magnitudeand polarity to the access lines 104, 106, which can both select memorycell 100 and program memory cell 100.

In one embodiment, the access circuitry 143 applies a pulse with onepolarity to program the memory cell 100 to be in one logic state, andapplies a pulse with a different polarity to program the memory cell 100to be in a different logic state. The access circuitry 143 can thendifferentiate between different logic states as a consequence of theprogramming polarity of a memory cell. For example, in a case of amemory read, the access circuitry 143 applies a voltage pulse with aparticular magnitude and polarity to the access lines 104, 106, whichresults in an electrical response that the sense circuitry 145 candetect. Detecting electrical responses can include, for example,detecting one or more of: a voltage drop (e.g., a threshold voltage)across terminals of a given memory cell of the array, current throughthe given memory cell, and a threshold event of the given memory cell.In some cases, detecting a threshold voltage for a memory cell caninclude determining that the cell's threshold voltage is lower than orhigher than a reference voltage, for example a read voltage. The accesscircuitry 143 can determine the logic state of the memory cell 100 basedon electrical responses to one or more of the voltage pulses in the readsequence.

The memory cell 100 is one example of a memory cell. Other embodimentscan include memory cells having additional or different layers ofmaterial than illustrated in FIG. 1 (e.g., a thin dielectric materialbetween the storage material and access lines).

FIG. 2 shows a portion of a memory cell array 200, which can include amemory cell such as the memory cell 100 of FIG. 1, in accordance with anembodiment. Memory cell array 200 is an example of a three-dimensionalcross-point memory structure (3D X Point). The memory cell array 200includes a plurality of access lines 204, 206, which can be the same orsimilar as the access lines 104, 106 described with respect to FIG. 1.Access lines 204, 206 can be referred to as bitlines and wordlines. Inthe embodiment illustrated in FIG. 2, the bitlines (e.g., access lines204) are orthogonal to the wordlines (e.g., access lines 206). A storagematerial 202 (such as the storage material 102 of FIG. 1) is disposedbetween the access lines 204, 206. In one embodiment, a “cross-point” isformed at an intersection between a bitline, a wordline. A memory cellis created from the storage material 202 between the bitline andwordline where the bitline and wordline intersect. The storage material202 can be a chalcogenide material such as the storage material 102described above with respect to FIG. 1. In one embodiment, the accesslines 204, 206 are composed of one or more conductive materials such asthe access lines 104, 106 described above with respect to FIG. 1.Although a single level or layer of memory cells is shown in FIG. 2,memory cell array 200 can include multiple levels or layers of memorycells (e.g., in the z-direction). Generally speaking, the intersectiondefines the address of the memory cell.

FIGS. 1 and 2 illustrate an example of a memory cell and array. However,other memory cell structures and arrays may be used, in which the memorycells exhibit electrical responses that vary as a function ofprogramming and read polarity.

FIG. 3 schematically shows how the polarity of programming and readvoltage pulses can affect the threshold voltage exhibited by a memorycell such as the memory cell 100 of FIG. 1. More particularly, FIG. 3 isa diagram illustrating an example of single-polarity read of a memorycell.

More in particular, in the example of FIG. 3, a memory cell 300 hasterminals 302A, 302B (labeled A and B, respectively) for accessing thememory cell 300. In one embodiment, terminals A and B are access lines,such as the access lines 104 and 106 of FIG. 1 or access lines 204 and206 of FIG. 2. Access circuitry (such as the access circuitry 143referred to in FIG. 1) can write to or read the memory cell 300 byapplying a voltage having a particular magnitude and polarity to theterminals 302A, 302B of the memory cell. For example, FIG. 3 shows a“positive” programming pulse 304 and a “negative” programming pulse 306.A positive programming pulse refers to a programming pulse with“positive polarity,” which can also be referred to as “forwardpolarity.” A negative programming pulse is a voltage pulse with“negative polarity,” which can also be referred to as “reversepolarity.” Whether or not a programming pulse is positive or negative isbased on the relative voltages applied to the terminals 302A, 302B. Avoltage pulse can be defined as positive if the voltage applied to oneof the terminals is more positive than the voltage applied to a secondof the terminals. For example, referring to FIG. 3, a positive voltagepulse can include: a positive voltage applied to terminal 302A and anegative voltage applied to terminal 302B; a positive voltage applied toterminal 302A and 0 V (e.g., circuit ground or neutral reference)applied to terminal 302B; 0V applied to terminal 302A and a negativevoltage applied to terminal 302B, a positive voltage applied to bothterminals 302A and 302B, but where the voltage applied to 302A isgreater than the voltage applied to 302B; or a negative voltage appliedto both terminals 302A and 302B, but where the voltage applied to 302Ais greater than the voltage applied to 302B.

In such an embodiment, a voltage pulse applied to the terminals of thememory cell would be negative if the voltage applied to terminal 302A ismore negative than the voltage applied to terminal 302B. For example, anegative voltage pulse can include: a negative voltage applied toterminal 302A and a positive voltage applied to terminal 302B; anegative voltage applied to terminal 302A and 0 V (e.g., circuit groundor neutral reference) applied to terminal 302B; OV applied to terminal302A and a positive voltage applied to terminal 302B, a negative voltageapplied to both terminals 302A and 302B, but where the magnitude of thevoltage applied to 302A is greater than the magnitude of the voltageapplied to 302B; or a positive voltage applied to both terminals 302Aand 302B, but where the magnitude of the voltage applied to 302B isgreater than the magnitude of the voltage applied to 302A.

FIG. 3 shows a particular definition of “positive” and “negative”relative to terminals 302A, 302B for illustrative purposes, however,embodiments can define positive and negative differently. For example,an embodiment can define a positive programming pulse to be a voltagepulse in which the voltage applied to terminal 302B is more positivethan the voltage applied to terminal 302A.

As mentioned above, access circuitry can both write to and read a memorycell by applying a voltage with a particular magnitude and polarity tothe cell. In one embodiment, access circuitry can write different valuesor logic states to the memory cell by applying voltages with differentpolarities. For example, the access circuitry can apply a positiveprogramming pulse (e.g., positive programming pulse 304) to write onelogic state, and a negative programming pulse (e.g., negativeprogramming pulse 306) to write a different logic state.

For ease of reference, the following description refers to a positiveprogramming pulse as writing a “logic 1” to memory cell, and a negativeprogramming pulse as writing a “logic 0” to a memory cell, although adifferent convention can be adopted. For example, in one embodiment,access circuitry can apply a negative programming pulse to write a logic1 and a positive programming pulse to write a logic 0. According to thepresent disclosure, the cell can thus have at least two logic states.

Whether or not a voltage applied to a memory cell programs the celldepends upon the magnitude and duration of the applied voltage. Forexample, in one embodiment, access circuitry applies a programmingpulse, such as the programming pulse 304 or 306, with a magnitudesufficient to cause the memory cell to threshold. For example, in oneembodiment, the access circuitry can apply a voltage with a magnitudethat is greater than or equal to the highest expected threshold voltageexhibited by the memory cell. In some embodiments the duration of aprogramming voltage pulse is 10 ns-50 ns. In some embodiments, theduration of the programming voltage pulse is 1-100 ns. In someembodiments, the duration of the programming voltage pulse is 1 ns-1 μs.In one embodiment, the duration of programming pulses and read pulses isthe same.

Different embodiments can involve applying read and write voltage pulsesof different shapes. In the embodiment illustrated in FIG. 3, theprogramming pulses 304 and 306 are shown as box-shaped pulses (alsoknown as rectangular-shaped or square-shaped pulses), and the readpulses 310, 312 are shown as ramped pulses. In one embodiment, the readpulses 310, 312 ramp up or down to a read voltage magnitude (e.g., to−V_(TH) High and −V_(TH) Low in the embodiment illustrated in FIG. 3).In actual implementations, the voltage pulses may have leading ortrailing edges, in accordance with embodiments. Other embodiments canapply write and read pulses having shapes such as triangular (e.g.,ramped pulses), trapezoidal, rectangular, box, and/or sinusoidal shapes.Thus, circuitry for accessing memory cells can apply programming pulseshaving a variety of shapes and durations sufficient to cause the memorycells to threshold into the desired state. In other words, the presentdisclosure is not limited by a particular shape of the write and readvoltages.

A method of reading memory cells involves applying a voltage pulse witha single polarity to the memory cell. For example, as mentioned above,FIG. 3 shows an example of a single-polarity read. In one suchembodiment, access circuitry applies a voltage pulse with only a singleparticular polarity to the memory cells. Sense circuitry can detect theelectrical response of a given memory cell to the single-polarity pulse.In the example illustrated in FIG. 3, reading the memory cell 300involves applying a negative voltage pulse, such as negative read pulses310 and 312. Although FIG. 3 illustrates negative read pulses 310, 312,access circuitry can also perform a single-polarity read using onlypositive voltage pulses to perform a single-polarity read.

If the read voltage pulse has a different polarity than the programmingpulse, such as in the case of positive programming pulse 304 andnegative read pulse 310, the memory cell exhibits a threshold voltagewith a higher magnitude (−V_(TH) High). In one such embodiment, if theread voltage pulse has the same polarity as the programming pulse, thememory cell exhibits a threshold voltage with a lower magnitude (−V_(TH)Low). In the embodiment illustrated in FIG. 3, the polarity of theresulting threshold voltage is negative because the read voltage pulsesare negative. Thus, when performing single polarity reads, the memorycell exhibits a threshold voltage with a higher magnitude (e.g.,|−V_(TH) High|) when the memory cell is in one logic state, and athreshold voltage with a lower magnitude (|−V_(TH) Low|) when the memorycell is in another logic state. Access circuitry can thus determine thelogic state of a given cell based on whether the memory cell exhibits ahigher or lower magnitude threshold voltage.

FIG. 4 is a graph showing exemplary threshold voltages with a higher andlower magnitude. The graph includes experimental data (thresholdvoltages) collected from memory cells in response to application ofdifferent programming currents. Thus, the x-axis of the graph is themagnitude (absolute value) of the programming current and the y-axis ofthe graph is the magnitude (absolute value) of the resulting thresholdvoltage in response to the programming current. As mentioned above,depending upon the programming and read polarities, the thresholdvoltage magnitude exhibited by a memory cell will be higher (e.g.,V_(TH) High) or lower (e.g., V_(TH) Low). The graph of FIG. 4 shows thatthe memory cells exhibit the higher and lower threshold voltages for arange of programming currents. This graph also shows that the higher andlower threshold voltages are actually ranges of voltages. For example,the higher threshold voltage magnitudes 320 are a range of magnitudesclustered at approximately 5.6V in the illustrated example. Similarly,the lower threshold voltage magnitudes 322 are a lower range ofmagnitudes approximately centered around 4.7V in the illustratedexample. In this example. the ranges of lower and higher thresholdvoltage magnitudes are separated by a window.

The window between the ranges of threshold voltage magnitudes can affectthe ability to reliably write to and read the memory cells. If thewindow between the threshold voltage ranges is sufficiently large (e.g.,if the ranges of threshold voltages are sufficiently spaced apart), thenaccess circuitry may be able to reliably distinguish between a logic 1and 0 in response to a single-polarity read. For example, if thethreshold voltage ranges are sufficiently spaced apart, access circuitrymay be able to accurately read the memory cell by applying a single readvoltage approximately at a mid-point between the low and high thresholdvoltages (e.g., about 5.1V as in FIG. 4). In one such example, applyinga single read voltage at the mid-point between the low and highthreshold voltages would cause memory cells programmed with the negativeprogramming pulse 306 to threshold, but not the memory cells programmedwith the positive programming pulse 304. Accordingly, access circuitrycould distinguish the logic state of the memory cells by determiningwhich memory cells thresholded in response to the single read voltage.However, if the window between the threshold voltage ranges is small, orif the threshold voltage ranges overlap, it can be difficult to reliablydistinguish between a logic 1 or 0 with a single-polarity read.

The following is a detailed description of further important propertiesof the cell distributions, with particular reference to FIGS. 5A-5B andFIGS. 6A-6B.

FIGS. 5A and 5B illustrate the effect of single-polarity reads withdifferent polarities. FIG. 5A is a scheme illustrating a single-polarityread with either a positive or negative voltage. Similar to FIG. 3, FIG.5A shows a memory cell 500 with two terminals 502A, 502B. Also similarto FIG. 3, FIG. 5A illustrates a positive programming pulse 504 and anegative programming pulse 506. FIG. 5A differs from FIG. 3 in that itshows the effects of positive and negative reads following positive andnegative programming pulses. Specifically, FIG. 5A shows positive readpulses 514 and negative read pulses 516. Note that although the readpulses 514, 516 are illustrated without a specific pulse shape, thepulses can be any suitable pulse shape, such as the pulse shapesdiscussed above with respect to FIG. 3, and the present disclosure isnot limited by the trend of the applied read voltage. Also note thatFIG. 3 and the following description are regarding a single-polaritypulse (either positive read pulses or negative read pulses, but not bothpositive and negative pulses for a given read).

When the applied voltage and the programming voltage have the samepolarity, the magnitude of the threshold voltage is low. For example, inthe embodiment illustrated in FIG. 5A, the positive programming pulse504 followed by the positive read pulse 514 results in V_(TH) Low1.Similarly, the negative programming pulse 506 followed by the negativeread pulse 516 results in −V_(TH) Low2. When the applied voltage and theprogramming voltage have different polarities, the magnitude of thethreshold voltage is high. For example, in the embodiment illustrated inFIG. 5A, the positive programming pulse 504 followed by the negativeread pulse 516 results in −V_(TH) High1. The negative programming pulse506 followed by positive read pulse 514 results in V_(TH) High2.

The magnitudes of higher and lower threshold voltages can vary. Forexample, in the example illustrated in FIG. 5A, V_(TH) High1 can bedifferent than V_(TH) High2. For example, memory cells exhibit differenthigh threshold voltage magnitudes that differ based on the polarity ofthe programming and read pulses. Specifically, the higher thresholdvoltage magnitude exhibited by a given memory cell when read with anegative voltage (e.g., the negative read pulse 516) is not necessarilythe same as a higher threshold voltage magnitude exhibited by the cellwhen read with a positive voltage (e.g., the positive read pulse 514).Similarly, memory cells can exhibit different lower threshold voltagemagnitudes that differ based on the polarity of the programming and readpulses. Specifically, the lower threshold voltage magnitude exhibited bya given memory cell when read with a positive voltage (e.g., thepositive read pulse 514) is not necessarily the same as a lowerthreshold voltage magnitude exhibited by the cell when read with anegative voltage (e.g., the negative read pulse 516).

In another example, the high threshold voltage magnitudes aresubstantially the same regardless of the polarity of the programming andread pulses. Similarly, the low threshold voltage magnitudes can besubstantially the same regardless of the polarity of the programming andread pulses. As is discussed below, high and low threshold voltagemagnitudes can also vary from memory cell to memory cell when read withthe same polarity. For example, memory cells located at differentlocations on a wafer can have different low and high threshold voltages.Thus, variations can exist in the magnitude of higher or lower thresholdvoltages due to, for example, read polarity and memory cell variations.Regardless of variations in high and low threshold voltages (e.g., dueto programming/read polarity or memory cell variations), a given memorycell may exhibits a high threshold voltage and a low threshold voltage,where the magnitude of the high threshold voltage is greater than themagnitude of the low threshold voltage.

FIG. 5B is a table illustrating outcomes of the single polarity readsillustrated in FIG. 5A. The table of FIG. 5B shows how, in accordancewith the embodiment illustrated in FIG. 5A, the read output from amemory cell is a function of the read and write polarities. The columnon the left is the programming polarity applied to the terminals 502A,502B of the memory cell 500. In the table of FIG. 5B, V_(A) refers tothe voltage applied to terminal A (502A) and V_(B) refers to the voltageapplied to terminal B (502B).

Thus, it is shown a case in which the programming polarity relative toterminal 502A is positive (V_(A)>V_(B)), and a case in which theprogramming polarity relative to terminal 502A is negative(V_(B)>V_(A)).

The middle Column shows the threshold voltage when the polarity of theread voltage pulse is positive, and the right column shows the thresholdvoltage when the polarity of the read voltage pulse is negative. Asexplained above, when the polarity of the programming and read pulses isthe same, the magnitude of the output voltage is low (e.g., |V_(TH)Low1| or |−V_(TH) Low2). When the polarity of the programming and readpulses is different, the magnitude of the output voltage is high (e.g.,|V_(TH) High1| or |V_(TH) High2). For example, when the higher thresholdvoltage has a magnitude of 5.7V and the lower threshold voltage has amagnitude of 4.7V, a positive programming pulse followed by a positiveread pulse results in a threshold voltage of 4.7V. A positiveprogramming pulse followed by a negative read pulse results in −5.7V. Anegative programming pulse followed by a positive read pulse results ina threshold voltage of 5.7V. A negative programming pulse followed by anegative read pulse results in a threshold voltage of −4.7V. Thus, themagnitude and the sign of the output of a read depends upon the polarityof the programming voltage and the polarity of the read voltage, inaccordance with an embodiment.

FIGS. 6A and 6B include graphs that show the ranges of threshold voltagemagnitudes as distributions. The graph of FIG. 6A illustrates thedistribution of threshold voltage magnitudes in response to a positivepolarity read. The graph of FIG. 6B illustrates the distribution ofthreshold voltage magnitudes in response to a negative polarity read. Inthe embodiment illustrated in FIGS. 6A and 6B, the distributions ofthreshold voltage magnitudes (|V_(TH)|) are normal (e.g., Gaussian). Asmentioned above, for illustrative purposes, FIGS. 6A and 6B adopts aparticular programming convention that assumes access circuitry appliesa positive programming pulse to program a cell to a logic 1, and anegative programming pulse to program the cell to a logic 0. However,another embodiment can adopt the opposite programming convention (e.g.,a positive programming pulse can result in a logic 0 and a negativeprogramming pulse can result in a logic 1).

Referring to the graph of FIG. 6A, the line 638 shows a distribution ofthreshold voltage magnitudes exhibited by memory cells programmed with alogic 1 when read with a positive voltage pulse. Thus, under theprogramming convention illustrated in FIGS. 6A and 6B, the line 638shows a distribution of threshold voltage magnitudes exhibited by amemory cell that is programmed and read with voltage pulses having thesame polarity. The line 638 therefore illustrates a distribution oflower threshold voltage magnitudes. The line 640 shows a distribution ofthreshold voltage magnitudes exhibited by memory cells programmed with alogic 0 and read with a positive voltage pulse. Thus, under theprogramming convention illustrated in FIGS. 6A and 6B, the line 640shows a distribution of threshold voltage magnitudes exhibited by amemory cell that is programmed and read with voltage pulses havingdifferent polarities (e.g., programmed with a negative voltage pulse andread with a positive voltage pulse). The line 640 therefore illustratesa distribution of higher threshold voltage magnitudes.

Referring to the graph of FIG. 6B, the line 634 shows a distribution ofthreshold voltages exhibited by memory cells programmed with a logic 0when read with a negative voltage pulse, in accordance with anembodiment. Thus, under the programming convention illustrated in FIGS.6A and 6B, the line 634 shows a distribution of threshold voltagesexhibited by a memory cell that is programmed and read with voltagepulses having the same polarity. The line 634 therefore illustrates adistribution of lower threshold voltages. The line 632 shows adistribution of threshold voltages exhibited by memory cells programmedwith a logic 1 when read with a negative voltage pulse. Thus, under theprogramming convention illustrated in in FIGS. 6A and 6B, the line 632shows a distribution of threshold voltage magnitudes exhibited by amemory cell that is programmed and read with voltage pulses havingdifferent polarities (e.g., programmed with a positive voltage pulse andread with a negative voltage pulse). The line 632 therefore illustratesa distribution of higher threshold voltage magnitudes.

As mentioned above, the distributions of higher and lower thresholdvoltages are separated by a window. For example, graph of FIG. 6A showsthat at the 50th percentile the distribution 638 and the distribution640 are separated by a window 642. Similarly, graph of FIG. 6B showsthat at the 50^(th) percentile the distribution 634 and the distribution632 are separated by a window 636. In embodiments, the windows 642 and636 can be the same or different depending on the relativedistributions. The graphs of FIGS. 6A and 6B also show that thedistributions of lower threshold voltage magnitudes and higher thresholdvoltage magnitudes can overlap, especially at the tails of thedistributions. For example, the graph of FIG. 6A shows a range ofthreshold voltage magnitudes in which the distributions 638 and 640overlap. Similarly, the graph of FIG. 6B shows a range of thresholdvoltage magnitudes in which the distributions 632 and 634 overlap. Theoverlaps can occur due to, for example, local variations of materialcomposition or dimensions of the individual memory cells. Therefore,when performing a single-polarity read, access circuitry that attemptsto read a memory cell that falls within the distribution overlap canmistakenly read a cell that is a logic 1 as a logic 0, or vice versa. Insome cases, error correction mechanisms can detect or correct sucherrors. However, if the distribution overlap is significant, then it maybe impractical to rely on error correction mechanisms to handle theerrors.

The above description has shown important properties of the celldistributions. In particular, the ranges of threshold voltages may thusoverlap in particular regions, particularly at the tails of thedistributions. As mentioned before, ideally, all memory cells shouldfeature a same (nominal) resistivity (and therefore a same thresholdvoltage, for a same logic state. However, since different cellsprogrammed to a same logic state exhibit different resistivity valuesbecause of several factors each logic state is actually associated to arespective resistivity distribution (typically a Gaussian-typedistribution), and therefore to a respective threshold voltagedistribution or range.

In order to assess the logic state of a Self-Selecting Memory (SSM) cell(e.g., a memory cells comprising a self-selecting memory material, suchas a chalcogenide material, the self-selecting material acting both asselection element and as a storage element), a reading operation iscarried out directed to assess to which threshold voltage distributionthe threshold voltage of the SSM cell belongs. For example, a readingvoltage may be applied to the SSM cell and the logic state of the SSMcell is assessed based on (the presence or absence of) a currentresponsive to said reading voltage, the (presence or absence of the)current depending on the threshold voltage of the SSM cell. It should beunderstood that a cell thresholds (e.g., it becomes conductive) when avoltage difference is applied between its two terminals.

According to the present disclosure, an advantageous read sequenceenables correctly reading values stored in memory cells even when thethreshold voltage distributions overlap. In this way, the embodimentsdisclosed allow to enlarge the sensing window (i.e., the differencebetween the voltage resulting from a logic “1” and a logic “0”) for aread operation, providing for a more accurate determination of the logicstate of the memory cell and thus reducing error rates.

As mentioned above, when the applied voltage and the programming voltagehave same polarity, the magnitude of the threshold voltage is low. Forexample, according to an embodiment of the present disclosureillustrated in FIG. 7, positive programming pulse 704 (corresponding toa logic state “1”) results in V_(TH) Low 1, for example as describedwith reference to FIGS. 5A and 5B. In at least some cases, the logicstate “1” may be determined by applying a positive read pulse 714, e.g.,whenever the memory cell thresholds when biased with positive read pulse714, resulting in said V_(TH) Low 1. When the applied voltage and theprogramming voltage have different polarities, the magnitude of thethreshold voltage is high. For example, negative programming pulse 706(corresponding to logic state “0”) results in V_(TH) High 1, when readin positive polarity. Therefore, cells in logic state “0” do notthreshold when biased with positive read pulse 714. Due to distributionoverlap (e.g., see FIG. 6A), some cells in logic state “1” do notthreshold when biased with positive read pulse 714 and are thereforeundistinguishable from cells in logic state “0”. Again, the shape of theread voltage may vary according to the needs or circumstances (e.g. itmay me a ramp, a squared pulse, and the like).

According to the embodiment of FIG. 7, the magnitude of a first readpulse applied to a plurality of cells, such as the first read pulse 714applied to the cell 700, is lower than the magnitude of a second readpulse 716, having the same polarity of the first read pulse 714. Inother words, FIG. 7 is similar to FIG. 5A except that FIG. 7 shows aread sequence in which the first applied voltage 714 in the readsequence is positive and followed by a second positive read voltage 716.As disclosed in greater detail below, a third pulse 718, having the samepolarity of the first and second read pulses, is subsequently applied.Even if the present disclosure refers to an embodiment wherein threeconsecutive positive read pulses are applied on cells programmed withpositive and/or negative read pulses, three consecutive negative readpulses can be used. Moreover, memory cells programmed with positiveprogramming pulse 704 followed by positive read pulse 716 results inV_(TH) Low 2, and memory cells programmed with positive programmingpulse 704 followed by positive read pulse 718 results in V_(TH) Low 3.Likewise, memory cells programmed with negative programming pulse 706followed by positive read pulse 716 results in V_(TH) High 2, and memorycells programmed with negative programming pulse 706 followed bypositive read pulse 718 results in V_(TH) High 3. The proportion betweenthe read pulses depicted in FIG. 7 is only for illustrative purpose andnonlimiting example.

As discussed below, access circuitry can determine the logic state ofmemory cells based on the electrical responses of the memory cells tothe application of a read voltage. According to the present disclosure,applying the a first read pulse with a suitable magnitude, such as thepulse 714 of FIG. 7, enables access circuitry to determine whether theprogramming voltage was positive (e.g., corresponding to a logic “1”state), or inconclusive. In one such embodiment, if access circuitrydetermines the programming polarity is inconclusive based on the firstread pulse, access circuitry can apply subsequent read pulses to resolvethe inconclusiveness. In this way, applying subsequent read pulses witha suitable magnitude enables access circuitry to discriminate betweenmemory cells that were programmed with a positive voltage (e.g.,corresponding to a logic “1” state) and a negative voltage (e.g.,corresponding to a logic “0” state), as discussed in greater detail inrelation to FIGS. 8A-8F.

For example, sense circuitry detects an electrical response of theplurality of memory cells to the applied voltage. Sense circuitry maydetect one of a voltage drop (e.g., a threshold voltage) acrossterminals of a given memory cell of the array, current through the givenmemory cell, and a threshold event of the given memory cell. In oneembodiment, detecting a threshold voltage for a memory cell can includedetermining that the cell's threshold voltage is lower than or higherthan a reference voltage. Based on the electrical response, accesscircuitry can determine the logic state of the memory cells or determinethat the state is inconclusive. In one embodiment in which the sensecircuitry is to detect current through a given memory cell, the accesscircuitry is to determine the given memory cell is in a logic statebased on detection that the current is greater or lower to a thresholdcurrent (i.e. based on the presence or absence of said current) inresponse to the applied voltage, said response depending on thethreshold voltage of the cell. In one embodiment, a threshold eventswitches the cell (e.g., the non-phase change chalcogenideself-selecting memory material) from a high resistivity to a lowresistivity state, resulting in a current that is greater than or equalto a threshold current. In one embodiment, the threshold current is inthe range of 1-10 μA (microamperes). However, other embodiments may havea threshold current that is lower than 1 μA or higher than 10 μAdepending on, for example, the storage material's properties (e.g.,conductivity of the storage material).

FIGS. 8A-8F and the corresponding descriptions illustrate how accesscircuitry can read memory cells using a read sequence such as thesequence shown in FIG. 7, in accordance with an embodiment of thepresent disclosure. More in particular, FIGS. 8A-8F are graphsillustrating distributions of threshold voltages exhibited by memorycells during performance of a read in accordance with an embodiment ofthe present disclosure.

Referring to FIG. 8A, the graph illustrates distributions 801, 803 ofthreshold voltages exhibited by memory cells programmed with logic 1 andlogic 0 respectively. In the embodiment illustrated in FIG. 8A, thedistribution 801 is for memory cells programmed and read with a positivepolarity. The distribution 803 is for memory cells programmed with anegative polarity and read with a positive polarity. Thus, points 802and 804 are threshold voltages for two different memory cells programmedto logic 1 with a positive voltage and read with a positive voltage.Points 806 and 808 are threshold voltages for two other memory cellsprogrammed to logic 0 with a negative voltage and read with a positivevoltage.

FIG. 8B illustrates application of a first read voltage (V_(DM1), whichcan correspond to the voltage of pulse 714 of FIG. 7) in a readsequence. In the illustrated embodiment, in accordance with the readsequence of the present disclosure, the first read voltage V_(DM1) has apositive polarity, and is thus “coherent” with the memory cellsprogrammed to logic 1 with a positive voltage. The magnitude of thefirst read voltage V_(DM1) is selected to be lower than an expectedlowest threshold voltage magnitude of cells programmed to the “0” logicstate, e.g., lower than the lowest threshold voltage of cells indistribution 803. The memory cells exhibit electrical responses to thefirst voltage, i.e. the memory cells can either threshold or notthreshold in response to V_(DM1). Whether or not a given memory cellthresholds in response to V_(DM1) depends on whether the memory cell isprogrammed to a logic 1 or logic 0, and whether or not the memory cellexhibits threshold voltages in the range of overlap between thedistributions. According to the present disclosure, a memory cellthresholds in response to an applied voltage if the applied voltage hasa magnitude that is greater than the threshold voltage thereof.Specifically, in reference to the FIG. 8B, the plurality of memory cellscan be grouped based on their response to the first voltage, including:memory cells that are programmed with a logic 1 that threshold inresponse to the first voltage (e.g., the group of memory cells includingthe cell corresponding to data point 802); memory cells that areprogrammed with a logic 0 that do not threshold in response to the firstvoltage (e.g., all the distribution 803, including points 806 and 808);and memory cells that are programmed with a logic 1, but that do notthreshold in response to the first voltage (e.g., the group of memorycells including the cell corresponding to point 804, i.e. cells thatexhibit a threshold voltage that falls within the overlap ofdistributions).

In one such embodiment, V_(DM1) has a polarity and magnitude tocorrectly identify the logic 1 memory cells that threshold in responseto the V_(DM1). For example, the magnitude of V_(DM1) is high enough tocause the memory cell corresponding to point 802 to threshold, and thusenable access circuitry to correctly read a logic 1. As illustrated,V_(DM1) is high enough to cause memory cells falling in the range 810 ofthe distribution (e.g., the lower part of the distribution 801) tothreshold, and thus enable access circuitry to read those memory cellsas a logic 1.

In addition to correctly ascertaining that all the memory cells in therange 810 are logic 1, application of V_(DM1) also refreshes orreinforces the data stored in the memory cells that threshold. In onesuch embodiment, the memory cells in the range 810 get reinforced inresponse to the first voltage because those memory cells experience athreshold event, and therefore the application of the first voltage hasa programming effect. In one such example, the read polarity is coherentwith program polarity of cells that threshold, so the read pulse andcorresponding threshold event has the same effect as a write pulse thatprograms the same logic state already stored in the memory cell. Thus,in one embodiment, application of the V_(DM1) is also able to refreshthe memory cells that threshold in response to the first voltage, whichcan prevent drift of the thresholding memory cells' state.

Memory cells that do not threshold in response to the first voltageV_(DM1) could be either memory cells programmed to logic 0, or memorycells programmed to a logic 1 that exhibit a threshold voltage with amagnitude higher than V_(DM1) (e.g., memory cells that exhibit athreshold voltage magnitude that falls within the overlap ofdistributions, in the high tail of the distribution 801, including point804). In the illustrated example, V_(DM1) has a magnitude that is lowerthan the magnitudes of all the threshold voltages of distribution 803(e.g., a magnitude that is lower than an expected lowest magnitude ofthe range defined by line 803). Therefore, in the illustratedembodiment, the memory cells programmed to logic 0 (including the memorycells corresponding to the data points 806 and 808) do not threshold inresponse to V_(DM1). Therefore, in a system performing a single read,the memory cell corresponding to point 804 would likely be readincorrectly as a logic 0. In accordance with an embodiment of thepresent disclosure, access circuitry determines that the logic state ofthe non-thresholding memory cells is inconclusive in response to V_(DM1)alone. Then, advantageously according to the present disclosure, accesscircuitry determines the logic state of such memory cells based on aread sequence, i.e. based on the memory cell responses to V_(DM1) and tosubsequent applied voltages having the same polarity, as discussedfurther below.

FIG. 8C shows the outcome of V_(DM1), i.e. of the first read voltage, inthe read sequence according to the present disclosure (data points ofcells in range 830 that have thresholded are purposely hidden becausetheir logic state has been unambiguously determined as “1”). Afterapplying V_(DM1), access circuitry is able to determine whether a givenmemory cell of the array is in the first logic state (e.g., logic 1 inthe illustrated example) or whether the given memory cell's logic stateis inconclusive based on the electrical responses to V_(DM1). Thus,access circuitry determines that the memory cells that threshold inresponse to V_(DM1) (e.g., memory cells in the range 830, correspondingto range 810 of FIG. 8B) are logic 1. The access circuitry alsodetermines that memory cells that do not threshold in response toV_(DM1) (e.g., memory cells in the range 832) could be either a logic 1or logic 0, and thus have a logic state that is inconclusive.

In one embodiment, the access circuitry is further configured to applysubsequent read voltages to discriminate between the memory cells thatare actually logic 0, and those that are logic 1 (e.g., logic 1 cells inthe high tail of the distribution 801).

According to the present disclosure, a second read voltage having thesame polarity and a different magnitude than V_(DM1) is applied. FIG. 8Dillustrates the distributions of threshold voltages in response to thesecond read voltage, indicated as V_(DM2). As discussed above, if amemory cell is programmed and read with the same polarity, it exhibits athreshold voltage having a magnitude in the lower distribution. Thus,the memory cells programmed to logic 1 with a positive voltage and thenread with positive voltage exhibit a threshold voltage having amagnitude falling in the lower range. The memory cells programmed tologic 0 with a negative voltage and then read with a positive voltageexhibit a threshold voltage having a magnitude in the higher range.

As discussed above, access circuitry is able to determine that thememory cells in the range 810 are a logic 1 in response to the firstread voltage. Therefore, because the access circuitry already determinedthe logic state of such memory cells in the range 810, the accesscircuitry can mask (e.g., screen) those memory cells from the secondread voltage. If access circuitry masks the memory cell from a voltage,the access circuitry does not apply such voltage to that memory cell, asshown in FIGS. 8C and 8D. In an embodiment, masking a cell correspond toswitch off (i.e. ground) the corresponding digit line. Accordingly,memory cells that have been determined to be in logic state 1 may bemasked in subsequent steps, in some examples.

FIG. 8D thus illustrates application of the second read voltage V_(DM2)in the read sequence of the present disclosure. In the illustratedembodiment, in accordance with the sequence of FIG. 7, also the secondvoltage has a positive polarity, and is thus “coherent” with the memorycells programmed to logic 1 with a positive voltage. The magnitude ofV_(DM2) is selected to be higher than an expected highest thresholdvoltage magnitude of cells programmed to the “1” logic state, e.g.,higher than the highest threshold voltage of cells in distribution 801.As before, the memory cells exhibit electrical responses to the secondvoltage, i.e. the memory cells can either threshold or not threshold inresponse to V_(DM2). Whether or not a given memory cell thresholds inresponse to V_(DM2) depends on whether the memory cell is programmed toa logic 1 or logic 0, and whether or not the memory cell exhibitsthreshold voltages in the range of overlap between the distributions(e.g., comprised between V_(DM1) and V_(DM2)). It should be understoodthat possible cells that have been masked in previous steps are notinterested in this operation; e.g., detecting second threshold voltagesexhibited by the plurality of memory cells in response to application ofthe second read voltage should be intended as detecting the secondthreshold voltage of unmasked memory cells. A memory cell thresholds inresponse to an applied voltage if the applied voltage has a magnitudethat is greater than the exhibited threshold voltage. Specifically, inreference to the FIG. 8D, the plurality of memory cells can be groupedbased on their response to the second voltage, including: memory cellsthat are programmed with a logic 1 that threshold in response to thesecond voltage (e.g., the group of memory cells including cellcorresponding to data point 804, i.e. cells that exhibit a thresholdvoltage that falls within the overlap of distributions); memory cellsthat are programmed with a logic 0 that threshold in response to thesecond voltage (e.g., the group of memory cells including the cellcorresponding to the point 808); and memory cells that are programmedwith a logic 0 that do not threshold in response to the second voltage(e.g., the memory cells including cell corresponding to the point 806,in the high part of distribution 803).

In one such embodiment, V_(DM2) has therefore a polarity and magnitudeto correctly identify logic 0 memory cells that do not threshold inresponse to said V_(DM2). The magnitude of V_(DM2) is high enough tocause all the memory cells programmed with logic 1 (i.e. the group ofcells including point 804) to threshold, as well as to cause the groupof cells including point 808 to threshold, but low enough to cause somememory cells (e.g. the group of cells including point 806 in FIG. 8D,falling in the range 820) programmed with logic 0 to not threshold andthus enable access circuitry to correctly read a logic 0 for theselatter cells. In other words, the second read voltage V_(DM2) is lowenough to cause memory cells falling in the range 820 of thedistribution (e.g., the higher part of the distribution 803) not tothreshold, and thus enable access circuitry to read those memory cellsas a logic 0.

Therefore, memory cells that threshold in response to the second readvoltage V_(DM2) could be either memory cells programmed to logic 1, ormemory cells programmed to a logic 0 that exhibit a threshold voltagewith a magnitude lower than V_(DM2) (e.g., memory cells that exhibit athreshold voltage magnitude that falls within the overlap ofdistributions). In the illustrated example, V_(DM2) has a magnitude thatis higher than the magnitudes of all the threshold voltages ofdistribution 801 (e.g., a magnitude that is higher than an expectedhighest magnitude of the range defined by line 801), in such a way thatall the memory cells programmed to logic 1 threshold in response toV_(DM2). At the same time, a memory cell that is programmed to logic 0,but that exhibits a threshold voltage that is on the low tail of thedistribution 803 (e.g., the group of cells including the cellcorresponding to point 808) may threshold in response to V_(DM2).According to the present disclosure, access circuitry determines thatthe logic state of such thresholding memory cells is inconclusive inresponse to V_(DM2).

As shown in FIG. 8D, after applying V_(DM2), access circuitry is thusable to determine whether a given memory cell of the array is in thesecond logic state (e.g., logic 0 as memory cells 820 in the illustratedexample) or whether the given memory cell's logic state is inconclusivebased on the electrical responses to V_(DM2) (i.e. cells that could beeither a logic 1 or logic 0).

Because the access circuitry already determined the logic state of thememory cells in the range 820, the access circuitry can mask (e.g.,screen) those memory cells from a subsequent read voltage. If accesscircuitry masks the memory cell from a voltage, the access circuitrydoes not apply a subsequent voltage to that memory cell, as shown inFIGS. 8E and 8F. In an embodiment, masking a cell correspond to switchoff (i.e. ground) the corresponding digit line. Accordingly, memorycells that have been determined to be in logic state 1 may be masked insubsequent steps, in some examples.

As shown in FIG. 8E, in addition to correctly ascertaining that all thememory cells in the range 820 are logic 0, application of V_(DM2) alsocauses the cells initially programmed with logic 0 and having athreshold voltage with magnitude lower than V_(DM2) (i.e. the cells inthe range of overlap, including point 808) to switch logic state, i.e.to be reprogrammed with the opposite logic state 1. In this way, suchcells reprogrammed with an opposite logic state (i.e. with the logicstate 1 in the illustrated example) have a threshold voltage that is nowlower than the lowest threshold voltage of the distribution 803 (i.e. ofall the cells initially programmed with logic 0), and also lower thanthat of the group of cells programmed with logic 1 and being in therange of overlap, i.e. the group cells including point 804.

In other words, some memory cells threshold in response to theapplication of V_(DM2) and change logic state (e.g. the group of cellsincluding point 808). In fact, because the polarity of the second readvoltage V_(DM2) is different than the polarity used to program the groupof memory cells including point 808, the application of V_(DM2) causesthose memory cells to change from a logic 0 to a logic 1. Accordingly,the access circuitry reprograms those memory cells after the applicationof V_(DM2). Therefore, after being reprogrammed, when read with positiveread voltage, the switched cells exhibit lower threshold voltages, inparticular analogous to those of the lower tail of the originaldistribution 801, and thus well separated from the highest part of suchdistribution 801 (i.e. well separated from the group of cells includingpoint 804, as shown in FIG. 8E).

According to the present disclosure, the access circuitry is thenconfigured to apply a subsequent third read voltage V_(DM3) todiscriminate between the memory cells that actually were programmed tologic 0, and those that were programmed to logic 1, as illustrated inFIG. 8F.

The third read voltage V_(DM3) has the same polarity and a differentmagnitude than the first read voltage V_(DM1) and the second readvoltage V_(DM2). FIG. 8F illustrates the distributions of thresholdvoltages in response to said third read voltage. As discussed above, ifa memory cell is programmed and read with the same polarity, it exhibitsa threshold voltage having a magnitude in the lower distribution. Thus,the memory cells that have been reprogrammed to logic 1 after theapplication of the second read voltage V_(DM2) (e.g., memory cellinitially programmed with negative programming pulse to in the low rangeof the logic 0distribution, such as cell 808), and then read with thethird positive voltage V_(DM3), exhibit a threshold voltage having amagnitude falling in the lower range. More in particular, since suchreprogrammed cells initially belonged to the lowest part (i.e. the tail)of the distribution 803 initially programmed with a logic 0, themagnitudes of the threshold voltages of these switched cells are nowlower than the lowest expected voltage of the remaining, not screened,group of cells initially programmed with logic 1, (i.e. the group ofcells in the range of overlap, including point 804, which is on the tailof the distribution 801). For this reason, the switched cells do notbelong to the region of overlap of the distributions anymore and can beeasily read with the third read voltage. It is in fact observed that theregion of overlap is generally at the tails of the cells distribution,so that the application of first and second voltages with a suitablemagnitude, and the subsequent masking of the cells whose logic state hasbeen determined, allows reading well-separated distributions for theremaining cells whose state has to be determined. It should beunderstood that possible cells that have been masked in previous stepsare not interested in this operation; e.g., detecting third thresholdvoltages exhibited by the plurality of memory cells in response toapplication of the third read voltage should be intended as detectingthe third threshold voltage of unmasked memory cells.

The third read voltage has a magnitude that is higher than the highestexpected magnitude of the threshold voltages of the switched cells (i.e.memory cells originally in the second logic state, or logic state 0,after they have been reprogrammed when applying the second read voltageV_(DM2), such as the switched group including point 808) and lower thanthe lowest expected voltage of the remaining group of cells initiallyprogrammed with logic 1, (i.e. the group including point 804). In theillustrated embodiment, in accordance with the sequence of FIG. 7, alsothe third voltage has a positive polarity, and is thus “coherent” withthe memory cells reprogrammed to logic 1 with a positive voltage. Asbefore, the memory cells exhibit electrical responses to the thirdvoltage, i.e. the memory cells can either threshold or not threshold inresponse to V_(DM3). In this case, whether or not a given memory cellthresholds in response to V_(DM3) depends on whether the memory cell hasswitched the logic state thereof during the application of the secondread voltage V_(DM2). Specifically, with reference to the FIG. 8F, thememory cells can be grouped based on their response to the thirdvoltage, including: memory cells that have been reprogrammed with alogic 1 that threshold in response to the third voltage (i.e., thememory cells including the cell corresponding to data point 808) becausesuch cells have now a threshold voltage whose magnitude is lower thanthat of V_(DM3); and memory cells that are initially programmed with alogic 1 that do not threshold in response to the third voltage (e.g.,the group of memory cells including point 804).

In one such embodiment, V_(DM3) has a polarity and magnitude tocorrectly identify the cells that do threshold in response to saidV_(DM3), and to associate to said cell the proper logic state 0 (becausesuch cells have been reprogrammed from logic 0 to logic 1 after theapplication of the second read voltage). The magnitude of V_(DM3) ishigh enough to cause all the reprogrammed memory cells to threshold, butlow enough to cause some memory cells (e.g. cells corresponding to point804) initially programmed with logic 1 to not threshold and thus enableaccess circuitry to correctly read a logic 1 for these latter cells.

In other words, as shown in FIG. 8F, after applying V_(DM3), accesscircuitry is able to determine whether a given memory cell of the arrayis in the first logic state (e.g., logic 1 in the illustrated example)or whether the given memory cell is in the second logic state (e.g.,logic 0 in the illustrated example) based on the electrical responses toV_(DM3). Therefore, memory cells that threshold in response to the thirdvoltage V_(DM3) are memory cells initially programmed to logic 0 andaccess circuitry determines that the logic state of such thresholdingmemory cells is 0 in response to V_(DM3), while the state of the cellthat do not threshold in response to V_(DM3) is 1.

Therefore, according to the read sequence of the present disclosure, itis possible to read a plurality of cells with reduced error rates,because the read in the region of overlap is avoided and the windowbetween cell distributions is enhanced thanks to the application ofthree subsequent pulses having the same polarity and suitablymagnitudes.

All the above concepts can be applied also for a sequence of threenegative read pulses, wherein the negative polarity read pulses resultsin negative threshold voltage. Moreover, as explained before, in thiscase, the distribution of threshold voltage magnitudes for logic 0memory cells would be lower than the distribution of threshold voltagemagnitudes for logic 1 memory cells; all the other concepts of thepresent disclosure thus apply mutatis mutandis.

Table of FIG. 9 is a chart illustrating the outcomes of the readsequence in accordance with the description of FIGS. 8A-8F. The chartincludes four rows for memory cells programmed to logic 1 or logic 0,such rows corresponding to the portions in which the cells distributionsare ideally subdivided by the read operation according to the presentdisclosure. A “1” in the first column on the left refers to a memorycell that is initially programmed to a logic 1 (e.g., with a positiveprogramming voltage), and a “0” refers to a memory cell that isinitially programmed to a logic 0 (e.g., with a negative programmingvoltage). The remaining columns of the table indicate whether or not thememory cell thresholds in response to the read voltages according to thepresent disclosure.

According to an embodiment of the present disclosure, the selection ofthe proper read voltage V_(DMi) (i=1, 2 and 3) is obtained by definingsaid read voltage as the voltage that corresponds to a deterministicnumber of bit switched (i.e. read cells) during the application of readvoltages. At this regard, a per-codeword counter configured to accountfor the number of cells that undergo a threshold event during readingmay be used. In this case, in the reading operation, a voltage ramp isapplied, in such a way that the bias voltage is increased from astarting read voltage (e.g., ground zero voltage) until the number ofswitched bits, as counted by the counter, reaches a predetermined valuepreviously stored and corresponding to the proper magnitude of the readvoltage.

For example, according to this embodiment, if the total number of cellsprogrammed with logic 1 is J and the total number of cells programmedwith logic 0 is K, then the first read voltage corresponds to a rampapplied for a certain time until the number of switched bit is equal toaJ, where a is a<1 and is selected according to the needs andcircumstances (e.g. selected in such a way not to reach the region ofoverlap); this first portion of the ramp corresponds to the first readvoltage. Then, the ramp is continued until the number of switched bitsread is equal to J+bK, where b<1 and is selected according to the needsand circumstances; this second portion of the ramp thus corresponds tothe second read voltage. Then, after a given time, a new ramp is appliedand is increased from a starting read voltage (e.g., from zero voltage)until the number of switched bits read is equal to a preset valueaccounting for the cells that have reprogrammed to an opposite logicstate. This new ramp corresponds to the third read voltage. In someembodiments, the first and the second reading voltages are appliedindependently of the switched bits count and only the third reading usesan increasing ramped voltage until the count of bits in a predefinedstate (including the bits determined to be in the predefined stateduring the first and/or the second reading) matches the number of bitsin the codeword stored to be in that state.

In other words, according to this embodiment, the number of cells readis compared to a stored threshold value, so that the stop of the readramp is performed based of the number of cells read, thanks to thecounter.

In general, the third read voltage is applied after a given waitingtime, said time being determined with a dedicated test and beingconfigurable by design.

FIG. 10A is flow chart representing steps of a method according to thepresent disclosure. The processes described can be performed by hardwarelogic and circuitry. For example, the following processes are describedas being performed by access circuitry and sense circuitry, as disclosedherein. However, other embodiments can include different circuitryconfigurations suitable for performing the processes.

The method of the present disclosure is a method of performing a readsequence for reducing error rates in read operations of memory cells.Prior to reading the memory cells, access circuitry writes data to aplurality of memory cells. For example, access circuitry writes logic 0sand logic is to a plurality of memory cells such as the memory cell 100of FIG. 1. In one embodiment, access circuitry can write logic 0s byapplying programming pulses with a negative polarity and logic is byapplying programming pulses with a positive polarity. The oppositeconvention can also be adopted. After writing data to the plurality ofmemory cells, access circuitry can read the plurality of memory cellsusing the read sequence of the present disclosure.

More in particular, at step 910, a first read voltage to a plurality ofmemory cells is applied. Then, at step 920, first threshold voltagesexhibited by the cells in response to application of the first readvoltage are detected. At step 930, a first logic state is thenassociated to one or more cells of the plurality of memory cells basedon the first threshold voltages detected in the previous step. In someembodiments, the first read voltage has a first magnitude that is lowerthan an expected smallest threshold voltage magnitude of memory cells inthe first logic state.

In contrast to conventional read techniques, the method of the presentdisclosure provides a further step 940 of applying a second read voltageto the plurality of memory cells, wherein the second read voltage hasthe same polarity of the first read voltage and a second magnitude thatis higher than a first magnitude of the first read voltage. In someembodiments, the second magnitude is higher than an expected highestthreshold voltage magnitude of memory cells in the first logic state. Insome embodiments, the one or more memory cells to which the first logicstate was associated to in step 930 are masked from the applying thesecond read voltage.

In a step 950, the method then provides detecting second thresholdvoltages exhibited by the plurality of memory cells in response toapplication of the second read voltage. Based on the second thresholdvoltages, a second logic state is then associated to one or more cellsof the plurality of memory cells at step 960.

Step 970 then provides applying a third read voltage to the plurality ofmemory cells, wherein the third read voltage has the same polarity ofthe first and second read voltages and is applied at least to a group ofmemory cells that, during the application of the second read voltage,have been reprogrammed to an opposite logic state. In some embodiments,the one or more memory cells to which the second logic state wasassociated to in step 960 are masked from the applying the third readvoltage. Step 980 provides detecting third threshold voltages exhibitedby the plurality of memory cells in response to application of the thirdread voltage. Finally, based on the third threshold voltages, step 990provides associating one of the first or second logic state to one ormore of the cells of the of the plurality of memory cells. Method 900may also include (not shown) reprogramming to an opposite logic state atleast memory cells that underwent a threshold event when biased atV_(DM2) (e.g., memory cells in the group of data point 808, forexample). Circuitry 142, including access circuitry 143 and sensecircuitry 145, may apply first, second and third voltages to memorycells, detect first, second and third threshold voltages and/orthreshold events and associate first and second logic states to memorycells according to the method and as described with reference to FIGS. 7and 8, in some embodiments.

FIG. 10B is a flow diagram representing steps of a method according toan embodiment of the present disclosure. At step 1010, a i-th readvoltage is applied to a plurality of memory cells. For example a firstread voltage V_(DM1) is applied to the memory cells. At step 1020, i-ththreshold voltages exhibited by those cells in response to applicationof the i-th read voltage are detected. For example, a threshold voltagelower than V_(DM1) is detected for those cells exhibiting a thresholdevent when biased to V_(DM1). At step 1030, a logic state is associatedto cells. For example a logic state 1 is associated to cells with athreshold voltage lower than V_(DM1) in step 1020. Other memory cellshave an undetermined state at this stage. At step 1040 a verification ismade whether the i-th read voltage has reached the last (k) readvoltage. If it has (Yes), the method ends at step 1050; if it has not(No) the method continues at step 1060, with masking said cells fromsubsequent steps. At step 1070 the I counter is incremented and themethod continues with applying the next (e.g., i+1) read voltage at step1010. For example V_(DM2) is applied to unmasked memory cells. Themethod may be carried out by circuitry 142, including access circuitry143 and sense circuitry 145, that may apply first, second and thirdvoltages to memory cells, detect first, second and third thresholdvoltages and/or threshold events and associate first and second logicstates to memory cells according to the method and as described withreference to FIGS. 7 and 8, in some embodiments.

As shown in FIG. 10B, once a cell is determined to be in a logic state(0 or 1), said cell can be masked (or screened) from subsequentreadings. According to the preferred embodiment of the presentdisclosure, at least three subsequent reading are performed to obtain aread operation with a greatly reduced number of steps, so that k may beequal to 3 in the flow chart of FIG. 10B. Method 1000 may also include(not shown) reprogramming to an opposite logic state at least memorycells that underwent a threshold event when biased at V_(DM2) (e.g.,memory cells in the group of data point 808, for example).

In other embodiments, the method 1000 comprises applying (1010) rampedread voltages, and the detecting threshold voltages (1020) comprisescounting how many cells undergo a threshold event and stopping each rampwhen the count matches a pre-determined number of cells in the givenlogic state (therefore adjusting the V_(DM1), V_(DM2) and/or V_(DM3)values based on the respective counts). Association of logic states tocells (1030) occurs based on threshold voltage detection (1020) at eachstep.

FIG. 11 is a high-level scheme of a system 1100 that can perform theread sequence of the present disclosure. The system 1100 includes amemory device 1110 in turn including an array of memory cells 1120 and acircuit portion 1130 operatively coupled to the memory cells 1120; thememory cells 1120 and the circuit portion 1130 form a memory portion,herein referred to as memory portion 1100′.

The memory device 1110 comprises a memory controller 1140, whichrepresents control logic that generates memory access commands, forexample in response to command by a host 1150. Memory controller 1140accesses memory portion 1100′. In one embodiment, memory controller 1140can also be implemented in the host 1160, in particular as part of ahost processor 1160, even if the present disclosure is not limited by aparticular architecture. The controller 1140 can include an embeddedfirmware and is adapted to manage and control the operation of thememory portion 1100′.

The memory device 1110 can also comprise other components, such asprocessor units coupled to the controller 1140, antennas, connectionmeans (not shown) with the host device, and the like.

Multiple signal lines couple the memory controller 1140 with the memoryportion 1100′. For example, such signal lines may include clock,command/address and write data (DQ), read DQ, and zero or more othersignal lines. The memory controller 1140 is thus operatively coupled tothe memory portion 1100′ via suitable buses.

The memory portion 1100′ represents the memory resource for the system1100. In one embodiment, the array of memory cells 1120 is managed asrows of data, accessed via wordline (rows) and bitline (individual bitswithin a row) control. In one embodiment, the array 1120 of memory cellsincludes a 3D crosspoint array such as the memory cell array 200 of FIG.2. The array 1120 of memory cells can be organized as separate channels,ranks, and banks of memory. Channels are independent control paths tostorage locations within memory portion. Ranks refer to common locationsacross multiple memory devices (e.g., same row addresses withindifferent devices). Banks refer to arrays of memory locations within amemory device. In one embodiment, banks of memory are divided intosub-banks with at least a portion of shared circuitry (e.g., drivers,signal lines, control logic) for the sub-banks. It will be understoodthat channels, ranks, banks, or other organizations of the memorylocations, and combinations of the organizations, can overlap physicalresources. For example, the same physical memory locations can beaccessed over a specific channel as a specific bank, which can alsobelong to a rank. Thus, the organization of memory resources will beunderstood in an inclusive, rather than exclusive, manner.

In one embodiment, the memory controller 1140 includes refresh (REF)logic 1141. In one embodiment, refresh logic 1141 indicates a locationfor refresh, and a type of refresh to perform. Refresh logic 1141 cantrigger self-refresh within memory, and issue external refreshes bysending refresh commands to trigger the execution of a refreshoperation.

In one embodiment, access circuitry 1131 of the circuit portion 1130performs a refresh (e.g., reprogramming) of any of the accessed memorycells that were not refreshed during the read sequence. Therefore, acomplete refresh of memory cells can be achieved as mostly a side effectof the memory read sequence with minimal additional refresh operations.

In an embodiment, the circuit portion can also be embedded in the memorycontroller, even if the present disclosure is not limited by aparticular architecture.

In the exemplary embodiment illustrated in FIG. 11, the memorycontroller 1140 includes error correction circuitry 1142. The errordetection/correction circuitry 1142 can include hardware logic toimplement an error correction code (ECC) to detect errors occurring indata read from memory portion. In one embodiment, errordetection/correction circuitry 1142 also corrects errors (up to acertain error rate based on the implemented ECC code). However, in otherembodiments, error detection/correction circuitry 1142 only detects butdoes not correct errors.

In the illustrated embodiment, the memory controller 1140 includescommand (CMD) logic 1143, which represents logic or circuitry togenerate commands to send to memory portion. The memory controller 1140may also include a counter 1144, such as the per-codeword counterdisclosed above and configured to count the number of bits switchedduring the read operation. Clearly, also other architectures can beemployed, for example the counter can be embedded in the host 1150 oralso in the circuit portion 1130.

Based on the received command and address information, access circuitry1131 of the circuit portion 1130 performs operations to execute thecommands, such as the read sequence of the present disclosure. In onesuch embodiment, the circuit portion 1130 includes sense circuitry 1132to detect electrical responses of the one or more memory cells to thefirst voltage and the second voltage. In one embodiment, the sensecircuitry 1132 include sense amplifiers. Figure illustrates the accesscircuitry 1131 and sense circuitry 1132 as being embedded in the memoryportion 1100′, however, other embodiments can include access circuitryand/or sense circuitry that is separate from the memory portion 1100′.For example, access circuitry and sense circuitry can be included in amemory controller such as the memory controller 1140.

In one embodiment, memory portion 1100′ includes one or more registers1133. The registers 1133 represent one or more storage devices orstorage locations that provide configuration or settings for theoperation of the memory portion.

Furthermore, in one embodiment, the circuit portion 1130 includes alsodecode circuitry 1134.

The host device 11500 represents a computing device in accordance withany embodiment described herein, and can be a laptop computer, a desktopcomputer, a server, a gaming or entertainment control system, a scanner,copier, printer, routing or switching device, embedded computing device,or other electronic device such as a smartphone. The memory device 1110may also be embedded in the host device 1150.

In one embodiment, the system 1100 includes an interface 1170 coupled tothe processor 1160, which can represent a higher speed interface or ahigh throughput interface for system components that needs higherbandwidth connections, and/or graphics interface components. Graphicsinterface interfaces to graphics components for providing a visualdisplay to a user of system 1100. In one embodiment, graphics interfacegenerates a display based on data stored in the memory device or basedon operations executed by processor or both.

The system may also comprise network interface 1180 communicativelycoupled to the host or to memory device for example for connecting withother systems, and/or a battery coupled to provide power to said system.

In conclusion, an example method for reading memory cells according tothe present disclosure comprises the steps of applying a first readvoltage to a plurality of memory cells, detecting first thresholdvoltages exhibited by the plurality of memory cells in response toapplication of the first read voltage, based on the first thresholdvoltages, associating a first logic state to one or more cells of theplurality of memory cells, applying a second read voltage to theplurality of memory cells, wherein the second read voltage has the samepolarity of the first read voltage and a higher magnitude than anexpected highest magnitude for said first threshold voltages, detectingsecond threshold voltages exhibited by the plurality of memory cells inresponse to application of the second read voltage, based on the secondthreshold voltages, associating a second logic state to one or morecells of the plurality of memory cells, applying a third read voltage tothe plurality of memory cells, wherein the third read voltage has thesame polarity of the first and second read voltages and is applied atleast to a group of memory cells that, during the application the secondread voltage, have been reprogrammed to an opposite logic state,detecting third threshold voltages exhibited by the plurality of memorycells in response to application of the third read voltage, and, basedon the third threshold voltages, associating one of the first or secondlogic state to one or more of the cells of the of the plurality ofmemory cells. A circuit portion, including access circuitry to apply theread voltages and to determine the logic states, and sense circuity todetect the threshold voltages, is also disclosed to perform the aboveoperations.

According to an embodiment, the memory cells exhibit a threshold voltagewith a higher magnitude when the memory cell is in the second logicstate, and a threshold voltage with a lower magnitude when the memorycell is in the first logic state, and wherein a logic state of a givencell is determined based on whether the memory cell exhibits a higher orlower magnitude threshold voltage in response to one of the applied readvoltages.

According to an embodiment, the second read voltage is applied only tomemory cells that where not determined to be in the first logic stateafter the application of the first read voltage.

According to an embodiment the third read voltage is applied only tomemory cells that were not determined to be in the second logic stateafter the application of the second read voltage.

According to an embodiment the first threshold voltages are within afirst range for cells of said plurality of memory cells programmed witha first polarity, the second threshold voltages are within a secondrange for cells of said plurality of memory cells programmed with asecond polarity, and the first range and second range partially overlap.

According to an embodiment, the first read voltage is lower than anexpected lowest threshold voltage of cells in the second logic state.

According to an embodiment, the second read voltage is higher than anexpected highest threshold voltage of cells in the first logic state.

According to an embodiment, the third read voltage is higher than ahighest expected threshold voltage of memory cells originally in thesecond logic state after the memory cells originally in the second logicstate have been reprogrammed when applying the second read voltage.

According to an embodiment, a magnitude of the second read voltage isgreater than a magnitude of the first read voltage.

According to an embodiment, a magnitude of the third read voltage islower than a magnitude of the second read voltage.

According to an embodiment, the third read voltage is selected as thevoltage that corresponds to a deterministic number of bits in apredefined state during the read operation, wherein the read voltage isincreased from a starting voltage until the number of counted bits inthe predefined state reaches a predetermined value.

According to an embodiment, the third read voltage is applied to thecells after a pre-determined waiting time.

Moreover, according to an embodiment, the sense circuitry is configuredto detect a first current through a given memory cell in response to thefirst read voltage, wherein the access circuitry is configured todetermine that the given memory cell is in the first logic state basedon detection that a magnitude of the first current is greater than orequal to a first threshold current.

According to an embodiment, the sense circuitry is configured to detecta second current through the given memory cell in response to the secondread voltage, wherein the access circuitry is configured to determinethat the given memory cell is at the second logic state based ondetection that a magnitude of the second current is less than a secondthreshold current.

According to an embodiment, the sense circuitry is configured to detecta third current through the given memory cell in response to the thirdread voltage, and wherein the access circuitry is configured todetermine that the given memory cell is at the second logic state basedon detection that a magnitude of the second current is greater than athird threshold current.

According to an embodiment, the access circuit is configured to mask thememory cells that have been assigned to a given logic state after theapplication of the first and/or the second read voltage.

According to an embodiment, the first read voltage applied by the accesscircuit has a lower magnitude than an expected lowest threshold voltageof memory cells in the second logic state and wherein the second readvoltage applied by the access circuit has a higher magnitude than anexpected highest threshold voltage of memory cells in the first logicstate.

In the preceding detailed description, reference is made to theaccompanying drawings that form a part hereof, and in which is shown, byway of illustration, specific examples. In the drawings, like numeralsdescribe substantially similar components throughout the several views.Other examples may be utilized, and structural, logical and/orelectrical changes may be made without departing from the scope of thepresent disclosure. In addition, as will be appreciated, the proportionand the relative scale of the elements provided in the figures areintended to illustrate the embodiments of the present disclosure andshould not be taken in a limiting sense.

As used herein, “a,” “an,” or “a number of” something can refer to oneor more of such things. A “plurality” of something intends two or more.As used herein, the term “coupled” may include electrically coupled,directly coupled, and/or directly connected with no intervening elements(e.g., by direct physical contact) or indirectly coupled and/orconnected with intervening elements. The term coupled may furtherinclude two or more elements that co-operate or interact with each other(e.g., as in a cause and effect relationship).

Although specific examples have been illustrated and described herein,those of ordinary skill in the art will appreciate that an arrangementcalculated to achieve the same results can be substituted for thespecific embodiments shown. This disclosure is intended to coveradaptations or variations of one or more embodiments of the presentdisclosure. It is to be understood that the above description has beenmade in an illustrative fashion, and not a restrictive one. The scope ofone or more examples of the present disclosure should be determined withreference to the appended claims, along with the full range ofequivalents to which such claims are entitled.

1. (canceled)
 2. A method, comprising: applying, with a first polarity,a first read pulse to a plurality of memory cells, wherein the firstread pulse comprises a first magnitude; identifying a first thresholdingevent of a first subset of the plurality of memory cells based at leastin part on applying the first read pulse to the plurality of memorycells; applying, with the first polarity, a second read pulse to theplurality of memory cells based at least in part on identifying thefirst thresholding event of the first subset of the plurality of memorycells, wherein the second read pulse comprises a second magnitude thatis different than the first magnitude; and determining a logic stateassociated with the first subset of the plurality of memory cells and asecond subset of the plurality of memory cells based at least in part onapplying the second read pulse to the plurality of memory cells.
 3. Themethod of claim 2, further comprising: identifying a second thresholdingevent of the first subset of the plurality of memory cells based atleast in part on applying the second read pulse to the plurality ofmemory cells, wherein determining the logic state associated with thefirst subset of the plurality of memory cells and the second subset ofthe plurality of memory cells is based at least in part on identifyingthe second thresholding event.
 4. The method of claim 2, furthercomprising: applying, with the first polarity, a third read pulse to theplurality of memory cells based at least in part on applying the secondread pulse to the plurality of memory cells, wherein the third readpulse comprises a third magnitude that is different than the firstmagnitude and the second magnitude.
 5. The method of claim 4, furthercomprising: identifying a third thresholding event of the first subsetof the plurality of memory cells based at least in part on applying thethird read pulse to the plurality of memory cells, wherein determiningthe logic state associated with the first subset of the plurality ofmemory cells and the second subset of the plurality of memory cells isbased at least in part on identifying the third thresholding event. 6.The method of claim 4, wherein the second magnitude is greater than thefirst magnitude and the first magnitude is greater than the thirdmagnitude.
 7. The method of claim 4, wherein the first read pulse, thesecond read pulse, and the third read pulse each comprise a positivepolarity or a negative polarity.
 8. The method of claim 2, furthercomprising: identifying an absence of the first thresholding event ofthe second subset of the plurality of memory cells based at least inpart on applying the second read pulse to the plurality of memory cells,wherein the first subset of the plurality of memory cells each comprisea first logic state based at least in part on identifying the firstthresholding event, and wherein the second subset of the plurality ofmemory cells each comprise a second logic state based at least in parton the absence of the first thresholding event.
 9. The method of claim2, wherein the first read pulse is associated with a voltage that islower than a threshold voltage of memory cells being programmed to afirst logic state.
 10. The method of claim 2, wherein the second readpulse is associated with a voltage that is greater than a thresholdvoltage of memory cells being programmed to a second logic state.
 11. Anapparatus, comprising: a plurality of memory cells; and a controllercoupled with the plurality of memory cells, wherein the controller isconfigured to cause the apparatus to: initiate applying, with a firstpolarity, a first read pulse to the plurality of memory cells, whereinthe first read pulse comprises a first magnitude; identify a firstthresholding event of a first subset of the plurality of memory cellsbased at least in part on applying the first read pulse to the pluralityof memory cells; initiate applying, with the first polarity, a secondread pulse to the plurality of memory cells based at least in part onidentifying the first thresholding event of the first subset of theplurality of memory cells, wherein the second read pulse comprises asecond magnitude that is different than the first magnitude; anddetermine a logic state associated with the first subset of theplurality of memory cells and a second subset of the plurality of memorycells based at least in part on applying the second read pulse to theplurality of memory cells.
 12. The apparatus of claim 11, wherein thecontroller is configured to cause the apparatus to: identify a secondthresholding event of the first subset of the plurality of memory cellsbased at least in part on applying the second read pulse to theplurality of memory cells, wherein determining the logic stateassociated with the first subset of the plurality of memory cells andthe second subset of the plurality of memory cells is based at least inpart on identifying the second thresholding event.
 13. The apparatus ofclaim 11, wherein the controller is configured to cause the apparatusto: initiate applying, with the first polarity, a third read pulse tothe plurality of memory cells based at least in part on applying thesecond read pulse to the plurality of memory cells, wherein the thirdread pulse comprises a third magnitude that is different than the firstmagnitude and the second magnitude.
 14. The apparatus of claim 13,wherein the controller is configured to cause the apparatus to: identifya third thresholding event of the first subset of the plurality ofmemory cells based at least in part on applying the third read pulse tothe plurality of memory cells, wherein determining the logic stateassociated with the first subset of the plurality of memory cells andthe second subset of the plurality of memory cells is based at least inpart on identifying the third thresholding event.
 15. The apparatus ofclaim 13, wherein the second magnitude is greater than the firstmagnitude and the first magnitude is greater than the third magnitude.16. The apparatus of claim 13, wherein the first read pulse, the secondread pulse, and the third read pulse each comprise a positive polarityor a negative polarity.
 17. The apparatus of claim 11, wherein thecontroller is configured to cause the apparatus to: identify an absenceof the first thresholding event of the second subset of the plurality ofmemory cells based at least in part on applying the second read pulse tothe plurality of memory cells, wherein the first subset of the pluralityof memory cells each comprise a first logic state based at least in parton identifying the first thresholding event, and wherein the secondsubset of the plurality of memory cells each comprise a second logicstate based at least in part on the absence of the first thresholdingevent.
 18. The apparatus of claim 11, wherein the first read pulse isassociated with a voltage that is lower than a threshold voltage ofmemory cells being programmed to a first logic state.
 19. The apparatusof claim 11, wherein the second read pulse is associated with a voltagethat is greater than a threshold voltage of memory cells beingprogrammed to a second logic state.
 20. A non-transitorycomputer-readable medium storing code comprising instructions which,when executed by a processor of an electronic device, cause theelectronic device to: initiate applying, with a first polarity, a firstread pulse to a plurality of memory cells, wherein the first read pulsecomprises a first magnitude; identify a first thresholding event of afirst subset of the plurality of memory cells based at least in part onapplying the first read pulse to the plurality of memory cells; initiateapplying, with the first polarity, a second read pulse to the pluralityof memory cells based at least in part on identifying the firstthresholding event of the first subset of the plurality of memory cells,wherein the second read pulse comprises a second magnitude that isdifferent than the first magnitude; and determine a logic stateassociated with the first subset of the plurality of memory cells and asecond subset of the plurality of memory cells based at least in part onapplying the second read pulse to the plurality of memory cells.
 21. Thenon-transitory computer-readable medium of claim 20, wherein theinstructions, when executed by the processor of the electronic device,further cause the electronic device to: identify a second thresholdingevent of the first subset of the plurality of memory cells based atleast in part on applying the second read pulse to the plurality ofmemory cells, wherein determining the logic state associated with thefirst subset of the plurality of memory cells and the second subset ofthe plurality of memory cells is based at least in part on identifyingthe second thresholding event.